Posts tagged CNS

Research led by Queen Mary, University of London, has opened up the possibility that drug therapies may one day be able to restore the integrity of the blood-brain barrier, potentially slowing or even reversing the progression of diseases like multiple sclerosis (MS). The study, funded by the Wellcome Trust, is published in Proceedings of the National Academy of Sciences.

The blood-brain barrier (BBB) is a layer of cells, including endothelial cells, which line the blood vessels in the brain and spinal cord. These cells act as a barrier, stopping certain molecules, including immune cells and viruses, passing from the blood stream into the central nervous system (brain and spinal cord).

In a number of neurodegenerative brain diseases, including MS, the BBB is compromised, allowing inappropriate cells to pass into the brain with devastating consequences.

In this study the researchers identified a specific protein – known as Annexin A1 (ANXA1) – as being integral in maintaining the BBB in the brain. The authors initially found that mice bred to lack this protein showed a decrease in integrity of the BBB compared to controls.

Taking this finding, they then investigated the potential role of ANXA1 in conditions which involve progressive breakdown of the BBB, including MS and Parkinson’s disease, by examining post-mortem human brain tissue samples. ANXA1 was present in the cells of samples from individuals who did not have a neurological disease and also in samples from patients who had died with Parkinson’s disease. However, it was not detectable in the endothelial cells in samples from patients who had died with MS.

Crucially, the researchers found that treating in vitro brain endothelial cells with human recombinant ANXA1 restored the key cellular features needed to reinstate the integrity of the BBB. The same was seen with the ANXA1 knockout mice, where administering the protein reversed the permeability of the BBB within 24 hours.

Dr Egle Solito, from Barts and The London School of Medicine and Dentistry, part of Queen Mary, who co-ordinated the study said: “Our findings suggest this protein plays a key role in maintaining a functioning BBB and, more importantly, has the potential to rescue defects in the BBB. We now need to carry on our research to see how much this molecule may be exploited for therapeutic uses in conditions such as MS, or as a biomarker to help in early diagnosis.”

(Source: qmul.ac.uk)

Drinking during pregnancy can have a severe, adverse effect on the central nervous systems of children after birth, researchers from Poland have discovered.

The study, which was presented Sunday at the annual meeting of the Radiological Society of North America (RSNA), looked at 200 children who were exposed to alcohol during their fetal stage, as well as 30 other kids whose mothers did not drink while pregnant or during lactation.

The researchers used a trio of different MRI techniques in order to study the brain development of both groups of subjects. First, they used standard MRI scans to observe the size and shape of the corpus callosum, which is a group of nerve fibers that oversees communication between the two halves of the brain.

Fetal alcohol exposure is believed to be one of the primary causes of impaired development of the corpus callosum, and sure enough, the MRI scans revealed those who had been exposed to alcohol had “statistically significant thinning of the corpus callosum… compared with the other group,” the RSNA said in a statement.

They also used diffusion weighted imaging (DWI) to study six areas of the central nervous system in both groups. The DWI technique maps the diffusion of water in the brain and can be more successful in detecting tissue abnormalities than regular MRI scans, the researchers explained.

Again, children who had been exposed to alcohol “exhibited statistically significant increases in diffusion on DWI” than their counterparts — an indication there had been damage to the brain tissue, or the presence of neurological disorders, according to Dr Andrzej Urbanik, chair of the Department of Radiology at Jagiellonian University.

Finally, they used proton (hydrogen) magnetic resonance spectroscopy (HMRS) to study the metabolism in the youngsters’ brains. The results uncovered “a high degree of metabolic changes that were specific for particular locations within the brain,” according to Dr. Urbanik.

The RSNA, citing US Centers for Disease Control and Prevention (CDC) statistics, reports as many as 1.5 out of every 1,000 children born alive suffer from fetal alcohol syndrome, and the costs of treating those victims tops $4 billion annually in America alone.

(Source: redorbit.com)

Scientists at the Mainz University Medical Center have discovered another molecule that plays an important role in regulating myelin formation in the central nervous system. Myelin promotes the conduction of nerve cell impulses by forming a sheath around their projections, the so-called axons, at specific locations – acting like the plastic insulation around a power cord. The research team, led by Dr. Robin White of the Institute of Physiology and Pathophysiology at the University Medical Center of Johannes Gutenberg University Mainz, recently published their findings in the prestigious journal EMBO reports.

Complex organisms have evolved a technique known as saltatory conduction of impulses to enable nerve cells to transmit information over large distances more efficiently. This is possible because the specialized nerve cell axonal projections involved in conducting impulses are coated at specific intervals with myelin, which acts as an insulating layer. In the central nervous system, myelin develops when oligodendrocytes, which are a type of brain cell, repeatedly wrap their cellular processes around the axons of nerve cells forming a compact stack of cell membranes, a so-called myelin sheath. A myelin sheath not only has a high lipid content but also contains two main proteins, the synthesis of which needs to be carefully regulated.

The current study analyzed the synthesis of myelin basic protein (MBP), a substance which is essential for the formation and stabilization of myelin membranes. In common with all proteins, MBP is generated in a two-stage process originating from basic genetic material in the form of DNA. First, DNA is converted to mRNA, which, in turn, serves as a template for the actual synthesis of MBP. During myelin formation, the synthesis of MBP in oligodendrocytes is suppressed until distinct signals from nerve cells initiate myelination at specific “production sites”. To date, the mechanisms involved in the suppression of MBP synthesis over relatively long periods of time have not been understood. This is where the current work of the Mainz scientists comes in, as they were able to identify a molecule that is responsible for the suppression of MBP synthesis.

"This molecule, called sncRNA715, binds to MBP mRNA, thus preventing MBP synthesis," explains Dr. Robin White. "Our research findings show that levels of sncRNA715 and MBP inversely correlate during myelin formation and that it is possible to influence the extent of MBP production in oligodendrocytes by artificially modifying levels of sncRNA715. This indicates that the recently discovered molecule is a significant factor in the regulation of MBP synthesis."

Understanding the molecular basis for myelin formation is essential with regard to various neurological illnesses that involve a loss of the protective myelin layer. For example, it is still unclear why oligodendrocytes lose their ability to repair the damage to myelin in the progress of multiple sclerosis (MS). “Interestingly, in collaboration with our Dutch colleagues, we have been able to identify a correlation between levels of sncRNA715 and MBP in the brain tissue of MS patients,” Robin White continues. “In contrast with unaffected areas of the brain in which the myelin structure appears normal, there are higher levels of sncRNA715 in affected areas in which myelin formation is impaired. Our findings may help to provide a molecular explanation for myelination failures in illnesses such as multiple sclerosis.”

(Source: uni-mainz.de)

In a new study appearing this month in the Journal of Neuroscience, researchers have unlocked the complex cellular mechanics that instruct specific brain cells to continue to divide. This discovery overcomes a significant technical hurdle to potential human stem cell therapies; ensuring that an abundant supply of cells is available to study and ultimately treat people with diseases. 

“One of the major factors that will determine the viability of stem cell therapies is access to a safe and reliable supply of cells,” said University of Rochester Medical Center (URMC) neurologist Steve Goldman, M.D., Ph.D., lead author of the study. “This study demonstrates that – in the case of certain populations of brain cells – we now understand the cell biology and the mechanisms necessary to control cell division and generate an almost endless supply of cells.”

The study focuses on cells called glial progenitor cells (GPCs) that are found in the white matter of the human brain. These stem cells give rise to two cells found in the central nervous system: oligodendrocytes, which produce myelin, the fatty tissue that insulates the connections between cells; and astrocytes, cells that are critical to the health and signaling function of oligodendrocytes as well as neurons.

Read more

Five scientists, including two from Simon Fraser University, have discovered that 30 per cent of our likelihood of developing Multiple Sclerosis (MS) can be explained by 475,806 genetic variants in our genome. Genome-wide Association Studies (GWAS) commonly screen these variants, looking for genetic links to diseases.

Corey Watson, a recent SFU doctoral graduate in biology, his thesis supervisor SFU biologist Felix Breden and three scientists in the United Kingdom have just had their findings published online in Scientific Reports. It’s a sub-publication of the journal Nature.

An inflammatory disease of the central nervous system, MS is the most common neurological disorder among young adults. Canada has one of the highest MS rates in the world.

Watson and his colleagues recently helped quantify MS genetic susceptibility by taking a closer look at GWAS-identified variants in the major histocompatibility complex (MHC) region in 1,854 MS patients. The region has long been associated with MS susceptibility.

The MS patients’ variants were compared to those of 5,164 controls, people without MS.

They noted that eight percent of our 30-per-cent genetic susceptibility to MS is linked to small DNA variations on chromosome 6, which have also long been associated with MS susceptibility.

The MHC encodes proteins that facilitate communication between certain cells in the immune system. Outside of the MHC, a good majority of genetic susceptibility can’t be nailed down because current studies don’t allow for all variants in our genome to be captured.

 “Much of the liability is unaccounted for because current research methods don’t enable us to fully interrogate our genome in the context of risk for MS or other diseases,” says Watson.

The researchers believe that one place to look for additional genetic causes of MS may be in genes that have variants that are rare in the population. “The importance of rare gene variants in MS has been illustrated in two recent studies,” notes Watson, now a postdoctoral researcher at the Mount Sinai School of Medicine in New York.

“But these variants, too, are generally poorly represented by genetic markers captured in GWAS, like the one our study was based on.”

(Source: sfu.ca)